FIELD OF THE INVENTION
[0001] The present application relates to the field of elevator auxiliary devices. More
specifically, the present application relates to a force application assembly, which
aims to enable an operator to remotely apply a force to an elevator car in a desired
direction. The present application also relates to an elevator including the above
force application assembly, and a method of elevator rescue.
BACKGROUND OF THE INVENTION
[0002] The elevator may stop due to a failure during daily operation, and under the action
of the load within an elevator car and a counterweight, the elevator car and the counterweight
will remain in a balanced position. At this point, the operator needs to use a dedicated
rescue device to apply a force to the car so that the car can leave its balanced position.
Existing rescue devices are usually designed to be used in cooperation with a speed
governor, and the speed governor is usually designed to be used with a closed loop
cable or a steel wire rope. For example, the rescue device can apply a force onto
the steel wire rope of the speed governor so as to move the car to a desired position,
thereby implementing subsequent rescue operations.
SUMMARY OF THE INVENTION
[0003] An object of one aspect of the present application is to provide a force application
assembly, which aims to enable an operator to remotely apply a force to components
of an elevator system. An object of another aspect of the present application is to
provide an elevator including the above force application assembly. An object of a
further aspect of the present application is to provide a method of elevator rescue.
[0004] The objects of the present application are achieved through the following technical
solutions.
[0005] A force application assembly is provided for applying a force to an elevator car
when the elevator car and a counterweight are in a balanced state, the force application
assembly including:
a first attachment portion, which is configured to be removably attached to an elevator
hoistway;
a second attachment portion, one end of which is removably fixed relative to the elevator
car or the counterweight, and which is configured to be at least partially elastic;
an actuation portion connected between the first attachment portion and the second
attachment portion, wherein the first attachment portion is configured to be fixed
relative to the actuation portion, and the second attachment portion is configured
to be movable relative to the actuation portion; and
an operation portion, which is associated with the actuation portion and is operable
to move the second attachment portion away from or close to the actuation portion;
wherein the actuation portion applies a force to the second attachment portion, and
the force is stored as elastic potential energy in the second attachment portion before
the balanced state of the elevator car and the counterweight is broken.
[0006] In the force application assembly described above, optionally, the first attachment
portion includes a hook so as to be removably attached to a fixing portion disposed
in the elevator hoistway.
[0007] In the force application assembly described above, optionally, the fixing portion
is disposed in one or more of the following positions: the bottom of the elevator
hoistway, or any side wall of the elevator hoistway.
[0008] In the force application assembly described above, optionally, the fixing portion
is correspondingly positioned directly under a compensation chain connection point
on the elevator car, or positioned directly under a compensation chain connection
point on the counterweight.
[0009] In the force application assembly described above, optionally, one end of the second
attachment portion is removably attached to a compensation chain under the elevator
car or under the counterweight.
[0010] In the force application assembly described above, optionally, the second attachment
portion includes an elastic first part and a rigid second part, and the first part
and the second part are connected together end-to-end in sequence.
[0011] In the force application assembly described above, optionally, the first part is
removably attached to the compensation chain, and the second part is attached between
the first part and the actuation portion.
[0012] In the force application assembly described above, optionally, the first part includes
one or more of the following devices: a compression spring, a torsion spring, a tension
spring, and an elastic piece.
[0013] In the force application assembly described above, optionally, the actuation portion
is configured to convert the action of the operation portion into a pushing force
or a pulling force applied to the second attachment portion in the length direction
of the second attachment portion.
[0014] In the force application assembly described above, optionally, the actuation portion
includes one or more of the following devices: a reversible chain mechanism, a pulley
block, a lever mechanism, and a gear mechanism.
[0015] In the force application assembly described above, optionally, the reversible chain
mechanism includes a hand chain block.
[0016] In the force application assembly described above, optionally, the operation portion
includes one or more of the following devices: a chain, a rope, and a rod.
[0017] In the force application assembly described above, optionally, the chain is configured
to have a closed shape, wherein the chain is engaged with the actuation portion at
one end of the closed shape, and is operable at the other end of the closed shape;
and wherein the chain is attached to a sprocket associated with the actuation portion.
[0018] In the force application assembly described above, optionally, the operation portion
is sized in such a way that an operator can operate the operation portion when the
operator is located outside the elevator hoistway.
[0019] In the force application assembly described above, optionally, the actuation portion
includes an actuator for applying a force to the second attachment portion, and the
operation portion includes a terminal for operating the actuator.
[0020] In the force application assembly described above, optionally, the actuator communicates
with the terminal through one or more of the following methods: electric wire, wired
network, Wi-Fi, Bluetooth, Zigbee, and telecommunication operator signal.
[0021] An elevator is provided, which includes the force application assembly described
above.
[0022] A method of elevator rescue is provided for changing the position of an elevator
car when the elevator car and a counterweight are in a balanced state, including the
following steps:
fixing the first attachment portion of the force application assembly relative to
the elevator hoistway;
fixing one end of the second attachment portion relative to the elevator car or the
counterweight;
applying a force to the second attachment portion through the actuation portion, so
that the force is stored as elastic potential energy in the second attachment portion
before the balanced state of the elevator car and the counterweight is broken; and
changing the position of the elevator car by using the elastic potential energy stored
in the second attachment portion.
[0023] In the method of elevator rescue described above, optionally, in the step of changing
the position of the elevator car, the elastic potential energy is used to break a
balanced force state of the elevator car by releasing an elevator brake device.
[0024] In the method of elevator rescue described above, optionally, the elevator brake
device includes a tractor brake mechanism.
BRIEF DESCRIPTION OF THE DRAWINGS
[0025] The present application will be described below in further detail with reference
to the accompanying drawings and preferred embodiments. Those skilled in the art will
appreciate that these drawings are drawn only for the purpose of explaining the preferred
embodiments and should not be construed as limiting the scope of the present application.
In addition, unless specifically stated, the drawings are only intended to conceptually
represent the composition or construction of the described objects and may contain
exaggerated illustration. The drawings are not necessarily drawn to scale.
FIG. 1 is a schematic structural view of an embodiment of an elevator according to
the present application.
FIG. 2 is a schematic view of a force application assembly according to an embodiment
of the present application during using.
FIG. 3 is a perspective view of a part of a force application assembly according to
an embodiment of the present application.
DETAILED DESCRIPTION OF THE EMBODIMENT(S) OF THE INVENTION
[0026] Hereinafter, preferred embodiments of the present application will be described in
detail with reference to the accompanying drawings. Those skilled in the art will
appreciate that these descriptions are merely illustrative and exemplary, and should
not be construed as limiting the scope of protection of the present application.
[0027] Firstly, it should be noted that the orientational terms such as top, bottom, upward,
and downward mentioned herein are defined with respect to the directions in various
drawings. These orientational terms are relative concepts, and therefore will vary
with the position and state thereof. Accordingly, these or other orientational terms
should not be interpreted as restrictive.
[0028] In addition, it should also be noted that for any single technical feature described
or implied in the embodiments herein, or any single technical feature shown or implied
in the drawings, it is still possible to combine these technical features (or their
equivalents) so as to obtain other embodiments that are not directly mentioned herein.
[0029] It should be noted that in different drawings, identical or substantially identical
components are denoted by identical reference signs.
[0030] FIG. 1 is a schematic structural view of an elevator. An elevator system 101 includes
a series of parts installed in a hoistway 117 which may be arranged across multiple
floors 125, and an elevator door may be respectively provided at each floor 125. The
elevator system 101 includes: a car 103, a counterweight 105, a traction wire 107,
a guide rail 109, a drive device 111, a position detection system 113, and a controller
115, etc. One end of the traction wire 107 is attached to the car 103, and the other
end of the traction wire 107 is attached to the counterweight 105. The counterweight
105 is configured to balance the weight of the car 103, and the traction wire 107
moves under the driving of the drive device 111, so as to selectively change the position
of the car 103 and make the car 103 stop at a desired floor. The traction wire 107
may be, for example, a rope, a steel cable, or a steel belt with a coating, and so
on. The traction wire 107 may also include a pulley mechanism or a pulley block (not
shown) to achieve desired raising and lowering operations. It is easy to understand
that the car 103 is also correspondingly provided with a door for personnel to enter
and exit the car 103.
[0031] The drive device 111 is provided at the top of the hoistway 117 and is configured
to adjust the positions of the car 103 and the counterweight 105. The drive device
111 can be any suitable power supply device, including but not limited to an electric
motor, etc. The drive device 111 may be powered by a power source line or power grid
(not shown).
[0032] The position detection system 113 can be installed to be fixed relative to the hoistway
117, and is preferably arranged at the top of the hoistway 117; for example, it may
be installed on a bracket or guide rail. The position detection system 113 is also
configured to sense the position of the car 103 in the hoistway 117, so as to provide
a position signal in relevant to the position of the car 103. In another embodiment,
the position detection system 113 may also be arranged on other parts, such as on
a moving part. The position detection system 113 may include an encoder, a sensor,
or other suitable sensing systems, and the sensing method includes, but is not limited
to, speed sensing, relative position sensing, absolute position sensing, digital encoding
sensing, and so on.
[0033] The controller 115 may be arranged in an independent control room 123, or may also
be arranged at other suitable positions. In an embodiment, the controller 115 may
also be arranged at a remote location or in the cloud. The controller 115 is configured
to control the operation of the entire elevator system 101. For example, the controller
115 can adjust the operation of the drive device 111 so as to make the car 103 and
the counterweight 105 start, accelerate, decelerate, stop, etc. The controller 115
may perform control operations according to a signal from the position detection system
113. In an embodiment, the controller 115 is configured to stop the car 103 at one
of the floors 125 and perform acceleration or deceleration movement between the floors
125.
[0034] FIG. 2 is a schematic view of a force application assembly according to an embodiment
of the present application during use, and FIG. 3 is a perspective view of a part
of a force application assembly according to an embodiment of the present application.
As shown in FIG. 2, when the elevator car and the counterweight are in a balanced
state (for example, when the elevator stops due to a failure during operation), the
car 103 and the counterweight 105 are operated by an elevator brake device (not shown)
to stop inside the hoistway 117. For example, the elevator brake device may be a tractor
brake mechanism. Top portions of the car 103 and the counterweight 105 may be connected
by the traction wire 107, and bottom portions of the car 103 and the counterweight
105 may be connected by a compensation chain or a compensation rope 108 (shown in
dotted lines). In the illustrated case, the position where the car 103 stops does
not match with a space 118 to which the hoistway 117 is attached. The space 118 may
be, for example, a hall which an elevator hall door faces, and so on. Therefore, in
this case, it is impossible for a rescuer or an operator 200 to directly open the
car door of the car 103 and perform the rescue operation.
[0035] As shown in FIGS. 2 and 3, a force application assembly 100 according to an embodiment
of the present application includes: a first attachment portion 110, which is configured
to be removably attached to the hoistway 117; a second attachment portion 120, one
end of which is removably fixed relative to the elevator car 103, and which is configured
to be at least partially elastic; an actuation portion 130 connected between the first
attachment portion 110 and the second attachment portion 120, wherein the first attachment
portion 110 is configured to be fixed relative to the actuation portion 130, and the
second attachment portion 120 is configured to be movable relative to the actuation
portion 130; and an operation portion 140 (shown in dashed lines), which is associated
with the actuation portion 130 and is operable to move the second attachment portion
120 away from or close to the actuation portion 130.
[0036] As shown in FIG. 3, the first attachment portion 110 may include a hook so as to
be removably attached to a fixing portion (not shown) provided in the hoistway 117.
The fixing portion may be provided in one or more of the following positions: the
bottom of the hoistway 117 and any side wall of the hoistway 117. In the embodiment
shown in FIG. 2, the fixing portion is correspondingly positioned directly under a
compensation chain connection point on the car 103.
[0037] As shown in FIG. 2, one end of the second attachment portion 120 is removably attached
to the compensation chain 108 under the car 103. In another embodiment, the second
attachment portion 120 may be removably attached to an attachment position on the
car 103. In any case, the second attachment portion 120 is directly or indirectly
attached to the car 103. As shown in FIG. 3, the second attachment portion 120 includes
an elastic first part 121 and a rigid second part 122, and the first part 121 and
the second part 122 are connected together end-to-end in sequence. The first part
121 is removably attached to the compensation chain 108, and the second part 122 is
attached between the first part 121 and the actuation portion 130. The first part
121 and the second part 122 may be respectively provided with a hook at each end,
so as to be removably attached together. In the embodiment shown in FIG. 3, the first
part 121 is a spring. In another embodiment, the first part includes one or more of
the following devices: a compression spring, a torsion spring, a tension spring, and
an elastic piece.
[0038] The actuation portion 130 may be configured to apply a force to the second attachment
portion 120, and the force is stored in the second attachment portion 120 as elastic
potential energy before being transmitted to the car 103, that is, stored in the first
part 121 with elasticity.
[0039] In the illustrated embodiment, the actuation portion 130 is configured to convert
the action of the operation portion 140 into a pushing force or a pulling force applied
to the second attachment portion 120 in the length direction of the second attachment
portion 120. The actuation portion 130 may include one or more of the following devices:
a reversible chain mechanism, a pulley block, a lever mechanism, and a gear mechanism.
In an embodiment, the reversible chain mechanism includes a hand chain block, and
the hand chain block may be installed invertedly. In another embodiment, the actuation
portion 130 includes a series of pulley blocks, so as to change the direction and
magnitude of the force from the operation portion 140.
[0040] The operation portion 140 may include one or more of the following devices: a chain,
a rope, and a rod. In the illustrated embodiment, the operation portion 140 is a chain
having a closed shape. The chain may be engaged with the actuation portion 130 at
one end of the closed shape, and is operable at the other end of the closed shape.
In an embodiment, the actuation portion 130 is associated with a sprocket (not shown),
and the chain is joined on the sprocket. When one end of the chain is cyclically pulled
by the operator, the other end of the chain will drive the sprocket to rotate and
drive the actuation portion 130 associated with the sprocket. In an embodiment, the
chain may be a hand chain block, or a hand-pulled chain with a reverse chain structure,
and the movement of the chain is transmitted to the actuation portion 130 through
the sprocket. The operation portion 140 may be sized in such a way that the operator
can operate the operation portion 140 when the operator is located outside the hoistway
117. For example, in the illustrated embodiment, the length of the operation portion
140 is sized to be long enough to extend from the bottom of the hoistway 117 to the
space 118 outside the hoistway 117, and may be operated by the operator 200 located
in the space 118.
[0041] In use, the operator can apply a force to the actuation portion 130 through the chain
140 so that the actuation portion 130 applies a pulling force or a pushing force to
the second attachment portion 120. These forces can be first stored in the elastic
first part 121 in the form of elastic potential energy, and selectively transmitted
to the car 103 to change the position of the car 103. Since the car 103 generally
has a larger mass, changing its position requires a larger force or a larger energy
consumption. The force application assembly described in the present application can
selectively apply a force having a limited magnitude that the operator can exert by
means of elastic potential energy, and can release the elastic potential energy accumulated
in a period of time within a relatively short time. Therefore, a sufficient force
is generated on the car 103 within a limited time, so as to change the position of
the car 103. In the illustrated embodiment, the force applied by the operator to the
second attachment portion 120 through the operation portion 140 tends to move the
car 103 downward, with the purpose of lowering the car 103 to a suitable height for
implementing subsequent rescue operations.
[0042] In another embodiment, the force application assembly 100 according to an embodiment
of the present application may be installed under the counterweight 105. For example,
the second attachment portion 120 may be attached to the compensation chain under
the counterweight 105, and the first attachment portion 110 may be attached to the
fixing portion under the counterweight 105. Correspondingly, the fixing portion may
be located directly under the compensation chain connection point on the counterweight
105. In this case, the force applied to the second attachment portion 120 by the operator
through the operation portion 140 tends to move the counterweight 105 downwardly.
The counterweight 105 drives the car 103 to move upwardly, with the purpose of raising
the car 103 to a suitable height for implementing subsequent rescue operations.
[0043] In another embodiment, the actuation portion 130 may include an actuator for applying
a force to the second attachment portion 120, and the operation portion 140 includes
a terminal for operating the actuator. The actuator may communicate with the terminal
through one or more of the following methods: electric wire, wired network, Wi-Fi,
Bluetooth, Zigbee, and telecommunication operator signal. In an embodiment, the actuator
is an electric motor. In another embodiment, the terminal includes a mobile phone,
a button, a notebook computer, etc.
[0044] In use, the operator can operate the actuator through the terminal, and the actuator
can apply a force to the second attachment portion 120. In any case, the operator
does not need to be inside the hoistway 117.
[0045] The present application also relates to an elevator, which includes the force application
assembly described above.
[0046] The present application also relates to a method of elevator rescue, which is used
to change the position of an elevator car when the elevator car and a counterweight
are in a balanced state (for example, when the elevator stops due to a failure during
operation). Specifically, the method of elevator rescue may include the following
steps:
fixing the first attachment portion 110 of the force application assembly 100 described
above relative to the hoistway 117;
fixing one end of the second attachment portion 120 relative to the car 103 or the
counterweight 105;
applying a force to the second attachment portion 120 through the actuation portion
130, so that the force is stored as elastic potential energy in the second attachment
portion 120 before the balanced state of the car and the counterweight is broken;
and
changing the position of the car 103 by using the elastic potential energy stored
in the second attachment portion 120.
[0047] In an embodiment, the step of changing the position of the car may include using
the elastic potential energy to break the balanced force state of the elevator car
by releasing an elevator brake device. The elevator brake device may include, for
example, a tractor brake mechanism. In another embodiment, the actuator 130 may periodically
or non-uniformly apply force to the second attachment portion 120 so as to intermittently
or continuously change the position of the car 103, thereby moving the car 103 to
a suitable position. In an embodiment, the force application assembly 100 lowers the
car 103 to a suitable position. In another embodiment, the force application assembly
100 raises the car 103 to a suitable position.
[0048] The force application assembly, the elevator, and the method of elevator rescue of
the present application enable the operator to change the position of the elevator
car through the force application assembly at a position outside the hoistway, thereby
realizing safe and effective elevator rescue. The technical solutions of the present
application have the advantages of being simple in structure, reliable in application,
and easy to implement, etc.
[0049] The present application has been disclosed herein with reference to the accompanying
drawings, and those skilled in the art are also enabled to implement the present application,
including manufacturing and using any device or system, selecting suitable materials,
and using any combined method. The scope of the present application is defined by
the claimed technical solutions, and contains other examples that can be conceived
by those skilled in the art. Such other examples should be considered as falling within
the scope of protection determined by the technical solutions claimed in the present
application, as long as such other examples include structural elements that are not
different from the literal language of the claimed technical solutions, or such other
examples include equivalent structural elements that are not substantively different
from the literal language of the claimed technical solutions.
1. A force application assembly provided for applying a force to an elevator car when
the elevator car and a counterweight are in a balanced state, the force application
assembly comprising:
a first attachment portion, which is configured to be removably attached to an elevator
hoistway;
a second attachment portion, one end of which is removably fixed relative to the elevator
car or the counterweight, and which is configured to be at least partially elastic;
an actuation portion connected between the first attachment portion and the second
attachment portion, wherein the first attachment portion is configured to be fixed
relative to the actuation portion, and the second attachment portion is configured
to be movable relative to the actuation portion; and
an operation portion, which is associated with the actuation portion and is operable
to move the second attachment portion away from or close to the actuation portion;
wherein the actuation portion applies a force to the second attachment portion, and
the force is stored as elastic potential energy in the second attachment portion before
the balanced state of the elevator car and the counterweight is broken.
2. The force application assembly according to claim 1, wherein the first attachment
portion comprises a hook, so as to be removably attached to a fixing portion disposed
in the elevator hoistway.
3. The force application assembly according to claim 2, wherein the fixing portion is
disposed in one or more of the following positions: the bottom of the elevator hoistway,
or any side wall of the elevator hoistway; and/or
wherein the fixing portion is correspondingly positioned directly under a compensation
chain connection point on the elevator car, or positioned directly under a compensation
chain connection point on the counterweight.
4. The force application assembly according to any preceding claim, wherein one end of
the second attachment portion is removably attached to a compensation chain under
the elevator car or under the counterweight.
5. The force application assembly according to any preceding claim, wherein the second
attachment portion comprises an elastic first part and a rigid second part, and the
first part and the second part are connected together end-to-end in sequence.
6. The force application assembly according to claim 5 when dependent on claim 4, wherein
the first part is removably attached to the compensation chain, and the second part
is attached between the first part and the actuation portion.
7. The force application assembly according to claim 5 or 6, wherein the first part comprises
one or more of the following devices: a compression spring, a torsion spring, a tension
spring, and an elastic piece.
8. The force application assembly according to any preceding claim, wherein the actuation
portion is configured to convert an action of the operation portion into a pushing
force or a pulling force applied to the second attachment portion in the length direction
of the second attachment portion.
9. The force application assembly according to claim 8, wherein the actuation portion
comprises one or more of the following devices: a reversible chain mechanism, a pulley
block, a lever mechanism, and a gear mechanism; and
optionally wherein the reversible chain mechanism comprises a hand chain block.
10. The force application assembly according to any preceding claim, wherein the operation
portion comprises one or more of the following devices: a chain, a rope, and a rod;
and optionally: wherein the chain is configured to have a closed shape, the chain
is engaged with the actuation portion at one end of the closed shape, and is operable
at the other end of the closed shape; and wherein the chain is attached to a sprocket
associated with the actuation portion.
11. The force application assembly according to any preceding claim, wherein the operation
portion is sized in such a way that an operator can operate the operation portion
when the operator is located outside the elevator hoistway.
12. The force application assembly according to any preceding claim, wherein the actuation
portion comprises an actuator for applying a force to the second attachment portion,
and the operation portion comprises a terminal for operating the actuator; and
optionally wherein the actuator communicates with the terminal through one or more
of the following methods: electric wire, wired network, Wi-Fi, Bluetooth, Zigbee,
and telecommunication operator signal.
13. An elevator comprising the force application assembly according to any one of claims
1 to 12.
14. A method of elevator rescue, which is used to change the position of an elevator car
when the elevator car and a counterweight are in a balanced state, the method comprising
the following steps:
fixing the first attachment portion of the force application assembly according to
any one of claims 1 to 12 relative to an elevator hoistway;
fixing one end of the second attachment portion relative to the elevator car or the
counterweight;
applying a force to the second attachment portion through the actuation portion, so
that the force is stored as elastic potential energy in the second attachment portion
before the balanced state of the elevator car and the counterweight is broken; and
changing the position of the elevator car by using the elastic potential energy stored
in the second attachment portion.
15. The method of elevator rescue according to claim 14, wherein in the step of changing
the position of the elevator car, the elastic potential energy is used to break the
balanced force state of the elevator car by releasing an elevator brake device; and
optionally wherein the elevator brake device comprises a tractor brake mechanism.